# What are optimal scrypt work factors?

I'm using a Java scrypt library for password storage. It calls for an `N`, `r` and `p` value when I encrypt things, which its documentation refers to as "CPU cost", "memory cost" and "parallelization cost" parameters. Only problem is, I don't actually know what they specifically mean, or what good values would be for them; perhaps they correspond somehow to the -t, -m and -M switches on Colin Percival's original app?

Does anyone have any suggestions for this? The library itself lists N = 16384, r = 8 and p = 1, but I don't know if this is strong or weak or what.

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Tip only: if the password storage data might be hijacked (i.e. if there is backup), then store not the encryption of password, but of password concatenated with access key. This prevents dictionary attacks. –  Joop Eggen Jun 20 '12 at 19:38
I've posted a generic answer for the question, but I would welcome more detailed answers with some CPU timing and memory usage statistics of course. –  Maarten Bodewes Jun 24 '12 at 14:18
@JoopEggen No idea what you want to say –  CodesInChaos Jun 24 '12 at 15:20
@Joop Eggen: No. SHA1 is not a Key derivation function, even with a salt. Do not use. SCrypt, on the other hand, is a very good one. Gladly enough, the OP is aware of the basic problem. –  gimpf Sep 11 '12 at 8:58
@JoopEggen it is not stated in this post but scrypt +requires+ an explicit salt to be passed as a parameter (beside N/r/p). And, by the way, it is highly recommended to use a +random+ salt provided by a cryptographically secure PRNG (I often use 16 or 32 bytes salt) –  Cerber Nov 20 '12 at 18:44

As a start:

cpercival mentioned in his slides from 2009 something around

• (N = 2^14, r = 8, p = 1) for < 100ms (interactive use), and
• (N = 2^20, r = 8, p = 1) for < 5s (sensitive storage).

These values happen to be good enough for general use (password-db for some WebApp) even today (2012-09). Of course, specifics depend on the application.

Also, those values (mostly) mean:

• `N`: General work factor, iteration count.
• `r`: blocksize in use for underlying hash; fine-tunes the relative memory-cost.
• `p`: parallelization factor; fine-tunes the relative cpu-cost.

`r` and `p` are meant to accommodate for the potential issue that CPU speed and memory size and bandwidth do not increase as anticipated. Should CPU performance increase faster, you increase `p`, should instead a breakthrough in memory technology provide an order of magnitude improvement, you increase `r`. And `N` is there to keep up with the general doubling of performance per some timespan.

Important: All values change the result. (Updated:) This is the reason why all scrypt parameters are stored in the result string.

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Btw, the scrypt parameters are automatically stored in the resulting key, so they don't need to be stored separately. This means you can have different values for the parameters in user passwords in the password storage as time passes and when users change their password, the key (=hashed password) is generated with the current parameter values. –  Kaitsu Nov 14 '12 at 16:25
Thanks for pointing this out; I didn't realize that the linked Java implementation does this in a sane way. –  gimpf Nov 15 '12 at 15:21